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LiDIA --- A library for computational number theory, developed 1994-2004 by Johannes Buchmann's group at TU Darmstadt, relicensed to GPL 2+ in 2006/2010. Extension for point-counting over finite fields of composite order.
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benediamond/LiDIA
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LiDIA --- A library for computational number theory LiDIA was developed from 1994 to 2004 at TU Darmstadt. It is not under active development. The authoritative repository for LiDIA used to reside at http://www.informatik.tu-darmstadt.de/TI/LiDIA/ftp/LiDIA/ The present version, named 2.3.0+latte-patches-YYYY-MM-DD, is based on the last official release, 2.3.0, of the LiDIA library. It has minimal patches for using LiDIA within the LattE integrale project with newer compilers and other infrastructure. It is maintained at https://github.com/mkoeppe/LiDIA LiDIA's build system has a mechanism to create two types of distribution archives: the whole archive (LiDIA-2.3.0) or just packages (LiDIA-base-2.3.0, LiDIA-FF-2.3.0, LiDIA-LA-2.3.0, LiDIA-LT-2.3.0, LiDIA-NF-2.3.0, LiDIA-EC-2.3.0, LiDIA-ECO-2.3.0, and LiDIA-GEC-2.3.0). All packages are provided in tar.gz format. Everything unpacks into the directory ./LiDIA-2.3.0. Package dependencies: base * The FF (Finite Fields) package depends only on the base package. | * The LA (Linear Algebra) package depends on the FF package. FF * The LT (Lattice) package depends on the LA package. | * The NF (Number Field) package depends on the LT package. LA * The EC (Elliptic Curve) package depends on the LA package. / \ * The ECO (Elliptic Curve Order) package depends on the EC package. LT EC * The GEC (Generate Elliptic Curves) package depends on both the NF | | and the ECO package. NF ECO \ / GEC CHANGES See the file NEWS for a list of major changes in the current release. C++ COMPILER REQUIREMENTS In order to compile LiDIA, your C++ compiler MUST support some ISO C++ features. These are: - type bool - inlining - mutable class members - explicit constructors - C++ style casts (i.e. static_cast<...> and const_cast<...>) - explicit template instantiation by ISO C++ - template specialization by ISO C++ (template <>) - ISO C++ headers, such as <iostream>, <fstream>, <string>, but also <cstdlib>, <cstdio>, etc. Moreover, LiDIA makes use of some basic classes from the C++ standard library, such as fstream, string. If your compiler fails to support one of the above items, you should upgrade. Sorry for the inconvenience, but that's what a standard is for. However, LiDIA still doesn't make use of exceptions and run-time type information if you don't want it to. As of release 2.1pre6, only g++ has been tested. The g++ versions 3.x and 4.x compile LiDIA successfully, whereas g++ 2.95.3 and 2.96 are known to fail when compiling LiDIA. Note that this is not LiDIA's fault... DISK SPACE AND MAIN MEMORY REQUIREMENTS LiDIA is a quite large system which requires a remarkable amount of resources. The full LiDIA distribution occupies about 70MByte when unpacked. Configuring and building all packages typically takes about 135MByte disk space on an i386-linux-gnu platform with ELF object file format, plus about 25MByte for temporaries. Installing all packages can take additional 90MByte. These amounts depend very much on the platform and on the configuration options. You can easily consume more than 1.8GByte if you configure LiDIA with configure --disable-shared CXXFLAGS='-O0 -g2' and run make check On the other hand, you can reduce the disk space requirements significantly by using appropriate configuration options if you do not need all the features of the full LiDIA distribution and if you build only those test programs you are interested in. With older versions of g++, 64MByte of RAM used to be sufficient for building LiDIA. Since recent g++ version have a much more heavy memory footprint, we recommend you have at least 512MByte free RAM. This recommendation also applies to building LiDIA applications, particularly when instantiating some of LiDIA's template classes. INSTALLATION (Unix-like systems, using configure) If you used `git clone` to obtain the source code of LiDIA, you will first have to generate the build scripts using: ./bootstrap Then proceed using `./configure' to configure LiDIA, see the file INSTALL for compilation and generic installation instructions. LiDIA-specific configure options: --enable-inline If set to `yes', the multi-precision arithmetic routines from the underlying kernel are inlined, otherwise separate function calls are generated. The default is `yes'. --enable-exceptions If set to `yes', then LiDIA is built with support for exceptions and errors are reported by exceptions. If set to `no', then LiDIA is built without support for exceptions. (g++ compiler switch `-fno-exceptions'.) Consult the description of class LiDIA::BasicError in the LiDIA manual for details. The default is `yes'. --enable-namespaces If set to `yes', then all of LiDIA's symbols will be defined in the name space LiDIA (your C++ compiler must support name spaces). The default is `yes'. --enable-assert If set to `yes', the assert macros will be activated by not defining `NDEBUG'. The default is `no'. --enable-ff If set to `yes', the finite-fields package will be built. The default is `yes'. --enable-la If set to `yes', the linear-algebra package will be built. Since this package depends on the finite-fields package, the linear-algebra package will be built only if the finite-fields package is built. The default is `yes'. --enable-lt If set to `yes', the lattice package will be built. Since this package depends on the linear-algebra package, the lattice package will be built only if the linear-algebra package is built. The default is `yes'. --enable-nf If set to `yes', the number-fields package will be built. Since this package depends on the lattice package, the number-fields package will be built only if the lattice package is built. The default is `yes'. --enable-ec If set to `yes', the elliptic-curves package will be built. Since this package depends on the lattice package, the elliptic-curves package will be built only if the lattice package is built. The default is `yes'. --enable-eco If set to `yes', the elliptic-curve-order package will be built. Since this package depends on the elliptic-curves package, the elliptic-curve-order package will be built only if the elliptic-curves package is built. The default is `yes'. --enable-gec If set to `yes', the elliptic curve generation package will be built. Since this package depends on the elliptic curve order package, the elliptic curve generation package will be built only if the elliptic curve order package is built. The default is `yes'. --with-arithmetic Determines the multi-precision kernel for LiDIA. Valid values are `gmp', `cln', `piologie', and `libI'. YOUR SYSTEM MUST PROVIDE THE LIBRARY OF YOUR CHOICE BEFORE CONFIGURING LiDIA! Note for Piologie users on Unix-like systems: For some reason the Piologie library is created as `piologie.a' instead of `libpiologie.a'. Rename `piologie.a' to `libpiologie.a', or create a link, otherwise the configure script will not find the Piologie library. --with-extra-includes If the headers of the multi-precision library reside in a directory that is not searched by your C++ compiler, then add the path with this option. --with-extra-libs If the multi-precision library resides in a directory that is not searched by your linker, then add the path with this option. LiDIA's build procedure uses GNU Libtool, which adds the following options to "configure": --enable-shared --enable-static These options determine whether shared and/or static library versions will be built. Only the latter option defaults to `yes'. --with-pic --without-pic Normally, shared libraries use position-independent code, and static libraries use direct jump instructions which need to be edited by the linker. The --with-pic option enforces position-independent code even for static libraries, whereas --without-pic does not demand position-independent code even when building shared libraries. Using one of these options can halven compilation time and reduce disk space usage because they save the source files from being compiled twice. Note that only position-independent code can be shared in main memory among applications; using position-dependent code for dynamically linked libraries just defers the linking step to program load time and then requires private memory for the relocated library code. --enable-fast-install LiDIA comes with some example applications, which you may want to run in the build tree without having installed the shared library. To make this work, Libtool creates wrapper scripts for the actual binaries. With --enable-fast-install=yes, the (hidden) binaries are prepared for installation and must be run from the (visible) wrapper scripts until the shared library is installed. With --enable-fast-install=no, the binaries are linked with the uninstalled library, thus necessitating a relinking step when installing them. As long as you do not run the hidden binaries directly and use the provided make targets for installing, you need not care about these details. However, note that installing the example applications without having installed the shared library in the configured libdir will work only with the setting --enable-fast-install=yes, which is the default. This can be important when preparing binary installation images. COMPILER FLAGS You can provide any desired compiler flag by setting the variable CXXFLAGS in the environment or in the command line passed to `configure'. For example, type ./configure CXXFLAGS="<your desired flags>" The configure script presets CFLAGS and CXXFLAGS with -O2, if these are empty or unset. If you have problems to build LiDIA due to memory exhaustion, it will probably help to limit inlining (some packages contain quite large inlined functions). If you are using GCC, the appropriate option to limit inlining is -finline-limit-N (GCC-2.x) resp. -finline-limit=N (GCC-3.x), where N should be chosen to be between 300 and 1000 (GCC's default is 10000). This will also result in faster compilation times and smaller object files for some source files. Likewise, the GNU g++ compiler flags -Wreturn-type might drastically increase memory consumption (see the GCC FAQ, e.g. http://gcc.gnu.org/faq/). Note that -Wall implies -Wreturn-type. EXTENDED FEATURES LiDIA's Makefile suite provides all targets proposed in the GNU Makefile standards, including `install-exec', `install-data', and `uninstall'. Furthermore, VPATH builds and staged installs (using DESTDIR) are supported. BUILDING AND INSTALLING THE EXAMPLES To build the examples, type make examples and to install the examples type make install-examples BUILDING THE DOCUMENTATION To run the documentation through LaTeX2e and produce the DVI file doc/LiDIA.dvi, type make dvi Note: As of release 2.1pre6, this also requires the "texi2dvi" script, which comes with the GNU texinfo tools, to be available on your system. You can additionally convert the DVI file into Postscript, yielding doc/LiDIA.ps, by running make ps and generate compressed versions doc/LiDIA.ps.{gz,bz2} using make psgz make psbz2 If you have pdflatex, you can as well build doc/LiDIA.pdf. Just type make pdf or make dsc The latter produces doc/LiDIA.dsc in addition to doc/LiDIA.pdf. The dsc file is a Postscript wrapper providing access to LiDIA.pdf for PS tools like psselect, Ghostview, and others. Making the dsc file requires the "pdf2dsc" utility which comes with Ghostscript 6.x. Note that the combination of pdf+dsc is as compact as a compressed PS file. However, you will probably not be able to print doc/LiDIA.dsc because that file uses pointers into LiDIA.pdf which will be dangling when copied into a spool directory. For printing, better make doc/LiDIA.ps. BUILDING THE MANUAL You can build the manual with "make doc" once the package is configured. Note that you need a (PDF-)LaTeX installation for this to work. If you do not have the EC and EM Type 1 fonts installed, then edit doc/LiDIA.tex and uncomment the line that instructs LaTeX to use the package ae. Using package "ae" will produce better-looking postscript output for on-screen viewing.
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LiDIA --- A library for computational number theory, developed 1994-2004 by Johannes Buchmann's group at TU Darmstadt, relicensed to GPL 2+ in 2006/2010. Extension for point-counting over finite fields of composite order.
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